Study Area

The study area is located in southern Brazil, in the Maquiné River basin (29°35'S, 50°16'W), Maquiné municipality, northeast of the state of Rio Grande do Sul (Fig. 1). This river basin is the southernmost distribution point of the Brazilian Atlantic rain forest stricto sensu [22]. The sampling areas were submontane rain forest and were restricted to altitudes between 125 and 450 meters above sea level. The climate is subtropical humid, with a mean annual temperature of 18°C, 1400 to 1800 mm of annual rainfall and no periods of drought.

Fig. 1.

Maquiné municipality in Rio Grande do Sul (RS) state, Brazil (left), and sample design in three valleys (right). Sampling unit labels are according to the cluster groups that considered 22 structural variables of sampling plots. S1 – structural stage 1: includes three point counts in initial areas and two in intermediate areas (defined according to the abandonment time; see methods); S2 – structural stage 2: includes one intermediate and two advanced; S3 – structural stage 3: includes three in advanced areas.

The landscape is a mosaic of secondary forests in different successional stages, with large areas covered by vegetation in initial stages of regeneration (22% of the land cover in the Maquiné river basin), intermediate stages (35%), and late stages (20%). All the forest stages originated from abandoned slash-and-burn agriculture. Old-growth forest was restricted to deep valleys, and 10% of the area was still used for agriculture [23, 24]. From the original vegetation cover of this river basin, approximately 70% was cleared for agriculture [24] and, at the time of the study, a large portion was regenerating naturally. Further details about the floristic and forest features of distinct successional stages can be found in Zanini et al. [23]. See also the results of habitat characterization below.

Sampling and data collection

The survey was carried out in three valleys approximately five km apart. One valley was within a conservation area (Reserva Biológica da Serra Geral). Areas were selected according to how long the forest had been regenerating, identified through interviews with local residents regarding the historical use of the land and the date of abandonment [23]. Field expeditions for physiognomic evaluations were also carried out. Sampling was then stratified by valley: sampling areas (three in each valley) were selected according to the date of abandonment (Fig. 1): initial (six to 10 years), intermediate (15 to 22 years) and advanced (more than 40 years). One of the nine sampling areas was an old-growth forest that had not been cleared, but had probably undergone selective logging during the past century.

For the quantitative survey of the avifauna we used the point count method [25] for sampling units (SU). For initial and intermediate stage areas, we undertook one point count, whereas for advanced areas we performed two. Initial and intermediate patches were too small to warrant more than one point count, whereas advanced forests were larger and more heterogeneous in terms of regeneration characteristics. Therefore, we intensified the sampling in such forests in order to better determine the relationship between bird assemblies and all the forest regeneration structures in the region. This design resulted in three SUs for initial stage forests, three for intermediate, and six for advanced, classified according to the date of abandonment. We also reclassified the forest stages according to structural characteristics measured in the field. Each SU had a 20 m fixed radius and the minimum distance between SUs was 100 m. Time spent sampling each point was 10 min. The 12 SUs were surveyed eight times between January and April 2010, resulting in 96 sampling events. Sampling was carried out between January and April because climate events (repeated floods) prevented us from sampling before, although the breeding season (spring/summer) is between September and early March [26, 27] and would be a more favorable time for bird sampling. Between March and April birds are less active, and some species migrate to northern Brazil [26] whereas others can still be found because of altitudinal migration [28]. As a result, new species were registered in the last sampling events leading to an increase in “rare” species in our data (see data analyses).

Surveys started 15 minutes after dawn and lasted for three hours. Each valley was sampled in one day, and we alternated the sampling sequence of stages within a valley. Each SU was sampled in all possible time intervals in order to take into account the effect of time of day on bird activity. All individuals seen and/or heard were documented, except for those that only flew over the area. The bird assembly was described by recording the number of birds per species for each SU in each sampling event. We used this method in order to compare bird assembly patterns in different stages of successional forests. The data also reflects to what extent each species uses the local resources.

Bird species were further classified into guilds based on food preference, following Willis [29], Motta-Junior [30], Sick [26], Aleixo [17], and Anjos [31], and foraging strata, following Willis [29], Stotz et al. [32], Sick [26], and Aleixo. Four strata were considered: ground (up to approximately one meter high), understory (from one meter to five meters), intermediate (trees between five meters and 15 meters) and canopy [17]. We used scientific nomenclature in accordance with the classifications established by the Brazilian committee of ornithological records [33].

To characterize the habitat and reclassify the SUs into structural stages, each successional area was described according to several vegetation structure variables provided by another study carried out on the same sites [23], which was part of a long-term project on permanent plots. Our SUs were in permanent plots, which were 0.25 ha for the initial and intermediate successional stages and 0.5 to 1 ha for the advanced stages. Randomly placed circular sub-plots of 100 m² were used to characterize the vegetation of each SU, with three in each 0.25 ha plot. In these sub-plots, we measured the habitat structural variables of the forest's upper stratum (tree specimens with DBH≥10 cm; DBH = diameter at breast height) and of the intermediate stratum (ligneous specimens with 1 cm<DBH<10 cm). For each stratum, we used 11 structural variables (Table 1). The structural variables were chosen to represent a wide range of vertical structures, tree density, and habitat complexity, measurements used to classify forest successional stages [2]. More detailed descriptions of plant species characterizing successional stages in these and adjacent areas of the Maquiné River basin can be found in Zanini et al. [23].

Table 1.

Structural variables used to characterize the forest habitat of sampling areas where bird assemblages were described.

Data analysis

To sort the SUs according to habitat structure, the matrix containing the SUs were described by structural variables and then cluster analyses were carried out, based on the Gower index for similarity between SUs and the incremental sum of squares as criteria for clustering [34]. The significance of clustering groups was tested using the bootstrap resampling method [35, 36]. The resulting groups (structural stages) were used to test for differences in richness, diversity, and the composition of bird assemblages. The same matrix underwent a principal coordinate analysis (PCA) to summarize the information from the structural variables and in order to describe the structural complexity of each SU and its respective cluster group.

To assess the response of bird species and guilds to changes in specific habitat structural parameters between SUs, we performed a canonical correspondence analysis (CCA) [37]. Structural variables that explained the variation were selected through the stepwise method and further tested by the Monte Carlo permutation method (using 999 random permutations).

Species richness and diversity patterns were compared between each clustering group. For species richness, we used a rarefaction analysis based on the number of records [38], to take into account the effect of differences in sampling effort. Species diversity was compared using the Hill series diversity profile, which correspond to different diversity indexes according to parameter a; from raw species richness (a = 0) to indices that give more weight to dominant species over rare ones [39]. Thus, comparisons between richness and equitability in each cluster group were possible, and the need for an arbitrary diversity index was avoided. Differences in species composition and guilds among cluster groups were tested through a multivariate variance analysis (MANOVA) with randomization (1000 permutations), based on chord distance as a measure of similarity between SUs [40]. We used the software Multiv [41] for PCA, MANOVA, and cluster analysis, PAST 1.84 [42] for rarefaction curves, and R [43] for the CCA and Hill series. In order to assess the influence of locally rare species in the observed patterns, assuming a potential bias of our sampling period, all analyses of the composition of bird species and guilds, richness, and diversity were repeated using the subset of the most frequent bird species (minimum record number = three).

Habitat Structure

The cluster analyses of the SUs described by habitat structural variables revealed three distinct groups (hereafter referred to as structural stages) (see Appendix 1). Stages 1, 2, and 3 had five, four, and three SUs, respectively. Note that this reclassification of structural stages was used for all comparative analyses. Stage 1 comprised initial and intermediate areas (between six and 22 years), stage 2 intermediate and advanced (from 15 to more than 40 years), and stage 3 only advanced areas (one of more than 40 years and two of old-growth forest). This classification did not coincide completely with that defined according to the abandonment date: one SU of 22 years was grouped with initial areas in stage 1, and one SU of more than 40 years, previously considered advanced, was clustered into stage 2.

The PCA of the SUs described by habitat structural variables revealed 62% of explanation in the first two axes (Fig. 2). The first component expresses variation in habitat complexity, distinguishing SUs in initial structural stages from those of late successional stages. Areas on the left side of the scatter diagram represent forests with a higher complexity of habitat structure: upper and intermediate strata with higher individuals, larger basal areas and variances in height and basal area, greater tree richness and abundance in the upper stratum (both total and among zoochorous species), and a greater number (and size) of standing dead individuals sampled in this stratum. The SUs in the right quadrants show lower values for all of these variables, besides an understory with higher values of abundance and richness (total and among zoochorous species) and higher abundance and basal areas of standing dead individuals sampled in the intermediate stratum. The second component shows habitat variations between stages 2 and 3: intermediate/advanced forests (stage 2) showed a higher variance between the individuals' height and the abundance of zoochorous species in the understory, whereas stage 3 showed larger proportions of total basal areas (for both strata) and a higher variance of basal areas for the upper stratum (due to the presence of bigger trees).

Fig. 2.

Scatter diagram of sampling units described by habitat structural variables, represented by the first two ordination axes (PCA). See labels for environmental variables in Table 1. Labels for sampling units correspond to the cluster groups (Appendix 1) – S1: stage 1, S2: stage 2, and S3: stage 3.

Bird richness, diversity and composition

We recorded 86 bird species (there were two we could not identify), distributed among 27 families (Appendix 2). Thraupidae (10 species) and Tyrannidae (nine species) were the best represented families with regard to species number. The CCA showed a significant relationship (P = 0.02) between bird species composition and seven selected structural variables (Fig. 3). The right side of the CCA scatter diagram shows segregation between species restricted to areas with higher structural complexity (for example the Green-throated Euphonia Euphonia chalybea, the Short-tailed Antthrush Chamaeza campanisona, the Gray-hooded Flycatcher Mionectis rufiventris, the Brown Tinamou Crypturelus obsoletus, and the Scaly-headed Parrot Pionus maximiliani), as well as species found in areas in the initial structural stage (for example the Chestnut-headed Tanager Pyrrhocoma ruficeps, the Rufous-browed Peppershrike Cyclarhis gujanensis, the Green-winged Saltator Saltator similis, and the Gray-bellied Spinetail Synallaxis cinerascens). Rarefaction showed that species richness was higher in stage 3, despite the lower number of records generated, compared to stages 1 and 2 (Fig. 4). Confidence intervals between stages 1 and 2 overlapped, indicating that richness did not differ between SUs in these stages. Diversity was also higher in stage 3 but only in comparison to stage 1, as shown throughout the Hill series (Fig. 5). Stage 2 did not differ from any other stage. Multivariate variance analysis revealed significant differences in bird species composition between stages 1 and 3 (P = 0.02), but not between stages 1 and 2 (P = 0.08) or 2 and 3 (P = 0.16).

Fig. 3.

Ordination diagram of the canonical correspondence analysis (CCA) relating avifauna to habitat structural variables in sampling units. Species with the highest correlation values with the first two axes are shown. Species labels: Atph Attila phoenicurus, Chca Chamaeza campanisona, Chcy Chlorophonia cyanea, Crob Crypturellus obsoletus, Cyca Cyanocorax caeruleus, Cygu Cyclarhis gujanensis, Drma Drymophila malura, Dyme Dysithamnus mentalis, Elin Eleoscytalopus indigoticus, Euch Euphonia chalybea, Eupe Euphonia pectoralis, Leam Leptopogon amaurocephalus, Miru Mionectes rufiventris, Myma Myiodynastes maculatus, Phgr Phyllomyias griseocapilla, Pima Pionus maximilianus, Pime Pipraeidea melanonota, Popl Poecilotriccus plumbeiceps, Pyru Pyrrhocoma ruficeps, Pyfr Pyrrhura frontalis, Sasi Saltator similis, Scsc Sclerurus scansor, Stla Stephanoxis lalandi, Syci Synallaxis cinerascens, Tacy Tangara cyanoptera Tase Tangara seledon, Thgl Thalurania glaucopis, Tuam Turdus amaurochalinus, Tyme Tyrannus melancholicus. Labels for environmental variables: first letter corresponds to stratum (U: upper stratum; I: Intermediate); second letter corresponds to structural variables (ni: number of individuals; mh: mean plant height; baV: variance of basal area; zoS: richness of zoochorous species; ba: sum of basal area; deB: basal area of standing dead individuals). Labels for sampling units: S1 - stage 1 (initial/intermediate); S2 - stage 2 (intermediate /advanced); S3 - stage 3 (advanced).

Fig. 4.

Rarefaction curves of bird species richness in the three structural stages, defined in cluster analysis. Labels for structural stages: S1 - stage 1 (initial/intermediate); S2 - stage 2 (intermediate/advanced); S3 - stage 3 (advanced).

Fig. 5.

Diversity profiles for the three structural stages defined in cluster analysis, using the Hill series. Labels for structural stages: S1 - stage 1 (initial/intermediate); S2 - stage 2 (intermediate/advanced); S3 - stage 3 (advanced).

Foraging guilds

We grouped the 86 species into 11 guilds: ground insectivores (four species), intermediate stratum insectivores (six), understory insectivores (25), canopy insectivores (five), ground omnivores (three), understory omnivores (nine), intermediate stratum omnivores (seven), canopy omnivores (17), canopy frugivores (six), understory nectarivores (three), and intermediate stratum nectarivores (one) (see Appendix 2).

Canonical correspondence analysis of guilds showed a significant relationship (P < 0.001) with five habitat structural variables (Fig. 6). The diagram distinguishes SUs in initial structural stages from advanced areas according to guild composition, and reflects guild turnover along the first axis, from stages 1 to 3. We did not find guilds exclusive to any single stage, except for canopy frugivores, which were restricted to stage 3. However, the right side of the diagram shows six guilds that were more closely associated with those habitat variables that represent higher structural complexity (stages 2 and 3): canopy frugivores, omnivores and insectivores, ground insectivores and omnivores, and understory omnivores. Guilds grouped on the diagram's left side, such as intermediate stratum omnivores and nectarivores, understory nectarivores and insectivores, were associated with forest areas with lower structural complexity. Results from the MANOVA regarding guild composition revealed significant differences between stage 1 and the other two stages (P= 0.01), but not between stages 2 and 3 (P = 0.34).

Fig. 6.

Ordination diagram of the canonical correspondence analysis (CCA) relating bird guilds (bold) to habitat structural variables (boxes) in sampling units (S1-3). Guilds labels: GI ground insectivore; II intermediate stratum insectivores; UI understory insectivores; CI canopy insectivores; GO ground omnivores; UO understory omnivores; IO intermediate stratum omnivores; CO canopy omnivores; CF canopy frugivores; UN understory nectarivores; IN intermediate stratum nectarivores. Labels for environmental variables: first letter corresponds to stratum (U: upper stratum; I: Intermediate); second letter corresponds to structural variables (deN: standing dead individual; deB: basal area of standing dead individuals; ba: sum of basal area; baV: variance of basal area). Labels for sampling units: S1 - stage 1 (initial/intermediate); S2 - stage 2 (intermediate/advanced); S3 - stage 3 (advanced).

Removing rare bird species

Among the 86 species sampled, 46 species did not reach the minimum of three records (hereafter called rare species). Thus, we reran all analyses with only the remaining 40 species. As expected, diversity and richness results shifted with the removal of rare species: stage 2 became more diverse than stages 1 and 3, but these two stages did not differ from each other, and all three stages did not differ in terms of rarefied richness. However, patterns of species and guild composition were alike. Therefore, MANOVAs of species and guild composition comparing structural stages had the same results across the entire species set: significant differences in species composition between stages 1 and 3 (P = 0.01), but not between stages 1 and 2 (P = 0.06) or 2 and 3 (P = 0.28). In relation to guild composition, we found significant differences between stage 1 and the other two stages (P = 0.01), but not between stages 2 and 3 (P = 0.45). The general pattern of guilds and species revealed in the CCAs analysis was also similar to that found in the whole species set (Appendix 3).